Method and apparatus for propagating error status over an ECC protected channel

ABSTRACT

System and methods for propagating error status over an error checking and correcting (ECC) protected channel. A first device receives data and an error status associated with the data. The first device generates check bits for the data based on a first ECC code and combines the check bits with the data to form one or more code words. The first device sends the code words across the channel where the first device inserts a triple error into a nibble of at least one codeword sent if the error status indicated an uncorrectable error. A second device connected to the channel receives the code words sent across the channel. The second device detects triple errors within a nibble of any code word and any other single error in the code word using a second ECC code, where the second ECC code is the first ECC code with columns for check bits inserted.

This application is a continuation of U.S. patent application Ser. No. 09/725,221, filed Nov. 29, 2000 now U.S. Pat. No. 6,622,268, entitled “Method and Apparatus For Propagating Error Status Over An ECC Protected Channel” which is incorporated by reference herein.

BACKGROUND

1. Field

This invention relates to data error reporting, and more specifically to propagating error status over an error checking and correcting (ECC) channel.

2. Background

Frequently, data that is read out of electronic devices, such as storage devices, input/output devices, etc., have parity bits or other types of check bits associated with the data. The check bits notify a receiver of the data whether the data being received is good data or whether the data has errors. If the data read from a memory or other source is to be received by one device and then sent to another device, the second receiving device needs to be aware that the data read (e.g., from a memory), is bad and has errors. However, if the error checking and correcting (ECC) that was used for the data in memory is different from the ECC used on the channel to send the data to the second receiving device, a different ECC code may need to be generated for the data that is read out of memory before sending the data to the second receiving device across the channel. Therefore, if data read from a memory or other device is corrupted (i.e., the data from memory has an uncorrectable error), the device receiving the data may compute new check bits with different ECC that is used on the channel, and send the data and new check bits to the second receiving device. At the second receiving device, everything looks fine regarding the validity of the data (since new check bits were generated), but this device may have actually received corrupted data. Therefore, the second receiving device needs to be notified that the data being received is corrupted and has an uncorrectable error.

One way to notify the second receiving device that the data being received has an uncorrectable error is to add an additional signal line to the second receiving device notifying this device when the data being received has an uncorrectable error. However, this requires the addition of another wire and possibly other hardware to the second receiving device. A second option is to purposely corrupt the data being sent to second receiving device again so that when the second receiving device receives the data it will detect an error. Since many channels and devices use single error correction (SEC) and double error detection (DED), injecting two errors into the data by the first receiving device before sending the data to the second receiving device will alert the second receiving device that the data has one or more uncorrectable errors. One way to inject two errors into the data is to flip two check bits before sending the data and check bits over the channel.

However, it is possible to get an additional error in the channel. If there is an error in the channel, this additional error may mask the injected errors, therefore, hiding the fact that the data contains an uncorrectable error. Therefore, a single bit error that occurs on the channel may alias the data to no error or to a single bit error, therefore, masking the uncorrectable error from the second receiving device. Since the first receiving device may be streaming data through the channel to the second receiving device, it is desired to insure that knowledge of uncorrectable errors get to the second receiving device.

Moreover, if the ECC code used at the second receiving device can only detect single and double bit errors, if four errors occur in the data sent across the channel, this may mask the fact that any error exists at all and the data may appear to have no errors to the second receiving device.

Therefore, a need exists for a more robust mechanism for propagating error status information over an ECC protected channel that is robust in the presence of single bit errors that may occur on the ECC protected channel.

BRIEF DESCRIPTION OF THE DRAWINGS

The present invention is further described in the detailed description which follows in reference to the noted plurality of drawings by way of non-limiting examples of embodiments of the present invention in which like reference numerals represent similar parts throughout the several views of the drawings and wherein:

FIG. 1 is a block diagram of an example system for propagating error status over an ECC protected channel according to an example embodiment of the present invention; and

FIG. 2 is a flowchart of an example process for propagating error status over an ECC protected channel according to an example embodiment of the present invention.

DETAILED DESCRIPTION

The particulars shown herein are by way of example and for purposes of illustrative discussion of the embodiments of the present invention. The description taken with the drawings make it apparent to those skilled in the art how the present invention may be embodied in practice.

Further, arrangements may be shown in block diagram form in order to avoid obscuring the invention, and also in view of the fact that specifics with respect to implementation of such block diagram arrangements is highly dependent upon the platform within which the present invention is to be implemented, i.e., specifics should be well within purview of one skilled in the art. Where specific details (e.g., circuits, flowcharts) are set forth in order to describe example embodiments of the invention, it should be apparent to one skilled in the art that the invention can be practiced without these specific details. Finally, it should be apparent that any combination of hard-wired circuitry and software instructions can be used to implement embodiments of the present invention, i.e., the present invention is not limited to any specific combination of hardware circuitry and software instructions.

Although example embodiments of the present invention may be described using an example system block diagram in an example host unit environment, practice of the invention is not limited thereto, i.e., the invention may be able to be practiced with other types of systems, and in other types of environments (e.g., servers).

Reference in the specification to “one embodiment” or “an embodiment” means that a particular feature, structure, or characteristic described in connection with the embodiment is included in at least one embodiment of the invention. The appearances of the phrase “in one embodiment” in various places in the specification are not necessarily all referring to the same embodiment.

The present invention is related to system and methods for reporting error status information from one portion of a system to another over an error checking and correcting (ECC) protected channel. In systems and methods according to the present invention, additional signal wires are not required on the channel. An ECC code is used to transmit error status information by using specific properties of the ECC code. Systems and methods according to the present invention provide a more robust mechanism for propagating error status information over an ECC protected interface since it is robust in the presence of single bit errors on the ECC protected interface (i.e., channel).

FIG. 1 shows a block diagram of an example system for propagating error status over an ECC protected channel according to an example embodiment of the present invention. A first device 10 sends one or more code words, that includes data and check bits, across an ECC protected channel or interface 20 to a second device 30. First device 10 includes a controller 12, a code word generator 16, and an error injector circuit 14. Other devices and/or applications may also be present at first device 10 and still be within the spirit and scope of the present invention. A second device 30 includes a syndrome processor 32 and an error classifier circuit 34. Similarly, other devices may be present at second device 30 and still be within the spirit and scope of the present invention. Device 10 receives data at code word generator 16, and receives error status associated with the data at controller 12.

The incoming data may come from any of many different types of sources, e.g., a memory device, a processor, an I/O (input/output) device, etc. The error status coming into device 10 may come from error checking circuitry that has checked the data from the memory or other device, and produced an error status. This error status may be that the data has no error, that the data has a correctable error, or that the data has an uncorrectable error. If the data had a correctable error, the error may have been corrected by the error checking circuitry before being received by device 10. If the error status indicates that the incoming data has an uncorrectable error, then the incoming data into device 10 still has errors associated with it.

The ECC used in the memory or other device that sends the data and error status to device 10 is different than the ECC code used before transmitting the data across channel 20 to second device 30. Therefore, first device 10 receives the data and error status, and generates new check bits on the data before sending the data and check bits in the form of a code word across channel 20 to second device 30. Syndrome processor 32 receives the data and check bits, re-computes check bits on the data, generates a syndrome, and compares the check bits generated with the check bits received across channel 20. If an error that is uncorrectable is detected, device 30 handles the data accordingly and may generate an error type signal from error classifier 34. Error classifier 34 classifies errors as, for example, no error, correctable error, or uncorrectable error.

The data coming into code word generator 16 may consist of data words of any of many lengths, e.g., 16 bit data word, 32 bit data word, 64 bit data word, etc. Code word generator 16 receives the data and creates check bits for each data word. Controller 12 receives the error status and if the error status indicates an uncorrectable error, controller 12 controls error injector circuitry 14 to inject a triple-bit error into a four bit nibble of the code word before the code word is transmitted across channel 20. Syndrome processor 32 receives the code word with the triple bit error inserted in a nibble of the code word, and is therefore able to determine that the data being received has an uncorrectable error. Further, if a code word is sent with a triple-bit error inserted into a nibble of the code word, and channel 20 also injects an additional single-bit error into the code word (therefore producing four errors in the code word), the syndrome processor is still able to detect that the receive data has an uncorrectable error.

Code word generator 16 uses an ECC code to determine how to generate check bits on the received data. The ECC code may be in the form of a matrix. The number of columns in the matrix may be determined by the length of a data word of the data. The number of rows in the matrix may be determined by the number of check bits generated on the data. An additional column is inserted in the ECC code matrix for every check bit that will be generated on the data. This forms a second ECC code matrix which may be used at the receiving device 30 to generate syndrome bits to determine the validity of the received data.

Below is shown an example ECC code with the check bit positions inserted. This code is based on a 64 bit data word, however, other matrices may be used that are based on other data word sizes and still be within the spirit and scope of the present invention. Example data with 64 bit words will be used to illustrate the present invention. The check bit positions shown in the ECC code are in positions that provide the ECC code with single four bit nibble error detection (S4ED) capability. If the check bits are all at the end of the code, the ECC code would only have the capability of single error correction (SEC) and double error detection (DED).

Example ECC Code

100010001000100010001000010000011100000000001111000011111111100011001001 010001000100010001000100010000110100000011110000111100001111100110001100 001000100010001000100010011000100100111100000000111111110000110011001000 000100010001000100010001110000110110111111111111000000000000100001001000 000000001111000011111111100011001001100010001000100010001000010000011100 000011110000111100001111100110001100010001000100010001000100010000110100 111100000000111111110000110011001000001000100010001000100010011000100100 111111111111000000000000100001001000000100010001000100010001110000110110                           cc      cc                          cc      cc

To help illustrate the present invention, we will call the above ECC code (with the check bits included), the H-matrix and the ECC code without the check bits the G-matrix. If you remove the check columns from the H-matrix you get the G-matrix, which is used to generate code words (i.e., at device 10). The H-matrix is used at the receiver (i.e., device 30) to check for errors in the received code words. Of course device 10 and device 30 may use the same ECC code (H-matrix) to perform their functions. Device 10 knows where to place the check bits into the code word based on the ECC code (H-matrix).

A check bit is generated for each row of the matrix (i.e, a data word). Eight check bits will be used also for this purpose. The example ECC code shown above is a (72,64) SEC-DED-S4ED code, i.e. the code length is 72 bits, the data length is 64 bits, and there are 8 check bits. Thus, since there are eight check bits in this example ECC code, there are eight rows in the ECC code. The check bit columns are denoted by a “c” at the bottom of the column, the other positions are data. A “1” in a check bit column denotes the check bit position for the particular row that the “1” resides in. For example, looking at the first check bit column, note that a “1” exists only in row three of this check bit column. This denotes that the check bit which is calculated on the data of row three is to be placed in this position. The number of check bits are selected based on a desired level of error detection and correction. This ECC code provides the property that triple errors within a nibble of a code word received plus any additional single error (i.e., injected by the channel) are detectable by a receiving side (e.g., device 30).

Code word generator 16 at device 10 receives the data and generates code words by first computing check bits on the data. The check bits are computed by taking the dot product of the G-matrix and the data. Each row of the G-matrix is used to generate a check bit, so there are 8 check bits. If c[i]=the ith check bit, d[j]=the jth data bit and G[i][j] is the G-matrix where G[0][0] is the upper left element, then: c[i]=XOR (d[j] AND G[i][j]) for j=0 to 63  (1) Since (d[j] AND G[i][j])=d[j] if G[i][j]=1, and 0 otherwise, the AND operation is not needed. Therefore, we may simply XOR the data bits for each j where G[i][j]=1. For example: c[0]=d[0] XOR d[4] XOR d[8] XOR d[12] XOR d[16]  (2)

At device 30, code words are checked by computing a syndrome, S, at syndrome processor 32. The syndrome is the dot product of the incoming code word, “w”, and the H-matrix. S[i]=XOR (w[j] AND H[i][j]) for j=0 to 72  (3) The syndrome is used by error classifier circuit 34 to classify errors. For this example ECC code:

if S=0==>no errors;

if S has odd weight:

-   -   if the nibbles of S have weights 3 and 2==>then triple error         within a nibble,     -   else==>this is a correctable error;     -   if S has even weight (and is non-zero)==>then this is an         uncorrectable error. The weight of a vector of 1's and 0's is         the number of 1's in the vector.

In systems and methods according to the present invention, a triple error is injected within a nibble, for example in d[0], d[1], and d[2]. The above ECC code (i.e., H-matrix) would detect this error as uncorrectable. Also, the ECC code has the property that in the event of a single error in any position (including 0, 1, and 2), the resulting syndrome will be non-zero and even weight, hence, the error will be detected as an uncorrectable error.

FIG. 2 shows a flowchart of an example process for propagating error status over an ECC protected channel according to an example embodiment of the present invention. Device A receives data and an associated error status S1. Device A then uses an ECC code to generate check bits on the data S2. Device A generates a code word for each data word in the data received S3. The code word includes the data word and the generated check bits. A determination is made by device A as to whether the error status indicates that the received data has an uncorrectable error S4. If the error status indicates no error, or correctable error (indicating that the error has already been corrected in the data), the code word that has been generated is left untouched S5. However, if the error status indicates that the received data has an uncorrectable error, device A injects a triple-bit error into a nibble of the code word S6.

Device A sends the code word across the channel to device B, S7. By injecting a triple-bit error into a nibble of the code word, device A is transmitting the fact that the data has an uncorrectable error to the receiving device. A single-bit error may be injected into the code word by the channel due to noise on the channel or other factors S8. If the channel has not injected any errors into the code word, the code word will remain with three errors, if device A determined that the data had an uncorrectable error S9. If the data has an uncorrectable error, the code word will have a triple-bit error inserted in it. If the channel further injects an additional single bit error, the code word will now contain four errors S10.

Device B receives the code word and regenerates the check bits on the data using the ECC code S11. Device B computes a syndrome and uses the syndrome to classify any errors detected S12. By using the ECC code at device B, both triple-bit error in a nibble of the code word, and a triple-bit error in the nibble of the code word as well as a single bit error caused by the channel in the code word will both be classified as uncorrectable errors S13. Therefore, device B will have been made aware of an uncorrectable error in the data and will handle the data accordingly S14. A single error injected by the channel or any other source may occur anywhere in the code word and still be detected based on the ECC code.

Therefore, in systems and methods according to the present invention, a more robust mechanism is provided for propagating error status information over an ECC protected interface. Systems and methods according to the present invention are robust in the presence of single bit errors on the ECC protected interface. Therefore, systems and methods for propagating error status information over an ECC protected channel according to the present invention are more reliable and the cost to implement are negligible.

It is noted that the foregoing examples have been provided merely for the purpose of explanation and are in no way to be construed as limiting of the present invention. While the present invention has been described with reference to a preferred embodiment, it is understood that the words which have been used herein are words of description and illustration, rather than words of limitation. Changes may be made within the purview of the appended claims, as presently stated and as amended, without departing from the scope and spirit of the present invention in its aspects. Although the present invention has been described herein with reference to particular methods, materials, and embodiments, the present invention is not intended to be limited to the particulars disclosed herein, rather, the present invention extends to all functionally equivalent structures, methods and uses, such as are within the scope of the appended claims. 

1. A method comprising determining that data has an uncorrectable error, and generating an error correction and detection code that comprises the data and a plurality of check bits such that the error correction and detection code indicates the uncorrectable error in the data regardless of a later introduced single bit error in the error correction and detection code.
 2. The method of claim 1 wherein generating the error correction and detection code comprises generating the error correction and detection code such that a receiving device can correct single bit errors, detect double bit errors, detect triple bit errors, and detect quadruple bit errors.
 3. The method of claim 2 wherein generating the error correction and detection code comprises injecting a triple bit error into the error correction and detection code.
 4. The method of claim 3 wherein injecting comprises injecting the triple bit error into a nibble of the error correction and detection code.
 5. The method of claim 1 wherein generating the error correction and detection code comprises generating the error correction detection code such that a device, based upon the error correction and detection code, can correct up to a X bit error in the error correction and detection code and can detect up to a Y bit error in the error correction and detection code, where Y is greater than or equal to X+3.
 6. The method of claim 5 wherein generating the error correction and detection code comprises injecting a Z bit error into the error correction and detection code, where Z is greater than X+1 and less than Y.
 7. A method comprising generating a code comprising data and a plurality of check bits such that a device, based upon the code, can correct up to a X bit error in the code and can detect up to a Y bit error in the code, where Y is greater than or equal to X+3, and injecting a Z bit error into the code in response to an uncorrectable error, wherein Z is greater than X+1 and less than Y.
 8. The method of claim 7 wherein X equals 1, Y equals 4, and Z equals
 3. 9. The method of claim 7 wherein injecting comprises injecting a triple bit error into a nibble of the code.
 10. An apparatus comprising a code generator to generate a code comprising data and a plurality of check bits that a device, based upon the code, can correct up to a X bit error in the code and can detect up to a Y bit error in the code, and an error injector to inject a Z bit error into the code in response to an uncorrectable error, wherein Z is greater than X+1 and less than Y.
 11. The apparatus of claim 10 comprising a controller to receive an error status of the data and to cause the error injector to inject the Z bit error in response to the error status indicating an uncorrectable error.
 12. The apparatus of claim 10 wherein X equals 1, Y equals 4, and Z equals
 3. 13. The apparatus of claim 10 wherein the error injector injects a triple bit error into a nibble of the code in response to the uncorrectable error.
 14. A machine-readable medium comprising a plurality of instructions that in response to being executed result in a device, determining whether data has an uncorrectable error, generating a code comprising data and a plurality of check bits such that another device, based upon the code, can correct up to a X bit error in the code and can detect up to a Y bit error in the code, and injecting a Z bit error into the code in response to determining that the data comprises has the uncorrectable error, wherein Z is greater than X+1 and less than Y.
 15. The machine-readable medium of claim 14 wherein executing the plurality of instructions further result in the device generating the code such that the another device can correct up to a single bit error and can detect up to a quadruple bit error, and injecting a triple bit error into the code in response to determining that the data has the uncorrectable error.
 16. The machine-readable medium of claim 14 wherein executing the plurality of instructions further result in the device injecting a triple bit error into a nibble of the code.
 17. A system comprising a receiving device to receive a code, to correct up to a X bit error of the code, to detect up to a Y bit error of the code, and to detect an uncorrectable error of the code in response to detecting that the code comprises greater than a X bit error, and a transmitting device to transmit the code such that the code comprises data, a plurality of check bits, and a Z bit error in response to the data having the uncorrectable error, where Z is greater than X+1 and less than Y.
 18. The system of claim 17 wherein X equals 1, Y equals 4, and Z equals
 3. 19. The system of claim 17 wherein the transmitting device injects a triple bit error into the code prior to transmitting the code.
 20. The system of claim 17 wherein the transmitting device injects a triple bit error into a nibble of the code prior to transmitting the code. 